Hypophosphatasia Explained

Hypophosphatasia
Pronounce:pronounced as //ˌhaɪpoʊˈfɒsfeɪtˌeɪʒə//
Field:Orthopedics, pediatrics, endocrinology
Synonyms:Phosphoethanolaminuria; Rathbun's syndrome
Symptoms:Variable—may include osteopenia, skeletal hypomineralization, respiratory compromise
Onset:Birth
Onset Always:y
Duration:Lifelong
Types:Infantile, childhood, adult, and odontohypophosphatasia
Causes:Mutation of the ALPL gene
Diagnosis:Comprehensive metabolic panel test for serum alkaline phosphatase level; examination of X-rays; genetic tests of ALPL
Differential:Osteogenesis imperfecta, congenital dwarfisms, skeletal dysplasias
Treatment:Asfotase alfa (Strensiq), an enzyme replacement therapy
Prognosis:Severe perinatal forms are lethal without treatment; adult forms may only show moderate symptoms
Frequency:Rare (1 in 100,000); more common in some populations

Hypophosphatasia (; also called deficiency of alkaline phosphatase, phosphoethanolaminuria,[1] or Rathbun's syndrome; sometimes abbreviated HPP) is a rare, and sometimes fatal, inherited[2] metabolic bone disease.[3] Clinical symptoms are heterogeneous, ranging from the rapidly fatal, perinatal variant, with profound skeletal hypomineralization, respiratory compromise or vitamin B6 dependent seizures[4] to a milder, progressive osteomalacia later in life. Tissue non-specific alkaline phosphatase (TNSALP) deficiency in osteoblasts and chondrocytes impairs bone mineralization, leading to rickets or osteomalacia.[2] The pathognomonic finding is subnormal serum activity of the TNSALP enzyme, which is caused by one of 388 genetic mutations identified to date, in the gene encoding TNSALP. Genetic inheritance is autosomal recessive for the perinatal and infantile forms but either autosomal recessive or autosomal dominant in the milder forms.

The prevalence of hypophosphatasia is not known; one study estimated the live birth incidence of severe forms to be 1:100,000.[5] and some studies report a higher prevalence of milder disease.[6]

Symptoms and signs

There is a remarkable variety of symptoms that depends, largely, on the age of the patient at initial presentation, ranging from death in utero to relatively mild bone problems with or without dentition symptoms[7] in adult life although neurological and extra-skeletal symptoms are also reported.[8] The stages of this disease are generally included in the following categories: perinatal, infantile, childhood, adult, benign prenatal and odontohypophosphatasia.[9] Although several clinical sub-types of the disease have been characterized, based on the age at which skeletal lesions are discovered, the disease is best understood as a single continuous spectrum of severity.

As the presentation of adult disease is highly variable, incorrect or missed diagnosis may occur. In one study, 19% of patients diagnosed with fibromyalgia had laboratory findings suggestive of possible hypophosphatasia.[10]

One case report details a 35-year old female with low serum ALP and mild pains but no history of rickets, fractures or dental problems. Subsequent evaluation showed osteopenia and renal microcalcifications and an elevation of PEA. The genetic mutations found in this case were previously reported in perinatal, infantile and childhood hypophosphatasia, but not adult hypophosphatasia.[7]

Perinatal hypophosphatasia

Perinatal hypophosphatasia is the most lethal form. Profound hypomineralization results in caput membranaceum (a soft calvarium), deformed or shortened limbs during gestation and at birth, and rapid death due to respiratory failure.[11] Stillbirth is not uncommon and long-term survival is rare. Neonates who manage to survive suffer increasing respiratory compromise due to softening of the bones (osteomalacia) and underdeveloped lungs (hypoplastic). Ultimately, this leads to respiratory failure. Epilepsy (seizures) can occur and can prove lethal.[12] Regions of developing, unmineralized bone (osteoid) may expand and encroach on the marrow space, resulting in myelophthisic anemia.[13] [14]

In radiographic examinations, perinatal hypophosphatasia can be distinguished from even the most severe forms of osteogenesis imperfecta and congenital dwarfism. Some stillborn skeletons show almost no mineralization; others have marked undermineralization and severe osteomalacia. Occasionally, there can be a complete absence of ossification in one or more vertebrae. In the skull, individual bones may calcify only at their centers. Another unusual radiographic feature is bony spurs that protrude laterally from the shafts of the ulnae and fibulae. Despite the considerable patient-to-patient variability and the diversity of radiographic findings, the X-ray can be considered diagnostic.

Infantile hypophosphatasia

Infantile hypophosphatasia presents in the first 6 months of life, with the onset of poor feeding and inadequate weight gain. Clinical manifestations of rickets often appear at this time. Although cranial sutures appear to be wide, this reflects hypomineralization of the skull, and there is often "functional" craniosynostosis. If the patient survives infancy, these sutures can permanently fuse. Defects in the chest, such as flail chest resulting from rib fractures, lead to respiratory compromise and pneumonia. Elevated calcium in the blood (hypercalcemia) and urine (hypercalcenuria) are also common, and may explain the renal problems and recurrent vomiting seen in this disease.[15]

Radiographic features in infants are generally less severe than those seen in perinatal hypophosphatasia. In the long bones, there is an abrupt change from a normal appearance in the shaft (diaphysis) to uncalcified regions near the ends (metaphysis), which suggests the occurrence of an abrupt metabolic change. In addition, serial radiography studies suggest that defects in skeletal mineralization (i.e. rickets) persist and become more generalized. Mortality is estimated to be 50% in the first year of life.[16]

Childhood hypophosphatasia

Hypophosphatasia in childhood has variable clinical expression. As a result of defects in the development of the dental cementum, the deciduous teeth (baby teeth) are often lost before the age of 5. Frequently, the incisors are lost first; occasionally all of the teeth are lost prematurely. Dental radiographs can show the enlarged pulp chambers and root canals that are characteristic of rickets.[17]

Patients may experience delayed walking, a characteristic waddling gait, stiffness and pain, and muscle weakness (especially in the thighs) consistent with nonprogressive myopathy. Typically, radiographs show defects in calcification and characteristic bony defects near the ends of major long bones. Growth retardation, frequent fractures, and low bone density (osteopenia) are common. In severely-affected infants and young children, cranial bones can fuse prematurely, despite the appearance of open fontanels on radiographic studies. The illusion of open fontanels results from hypomineralization of large areas of the calvarium. Premature bony fusion of the cranial sutures may elevate intracranial pressure.[18]

Adult hypophosphatasia

Adult hypophosphatasia can be associated with rickets, premature loss of deciduous teeth, or early loss of adult dentation followed by relatively good health. Osteomalacia results in painful feet due to poor healing of metatarsal stress fractures. Discomfort in the thighs or hips due to femoral pseudofractures can be distinguished from other types of osteomalacia by their location in the lateral cortices of the femora.[19] The symptoms of this disease usually begin during middle age of an adult patient and can include bone pain, and hypomineralization.[20]

Some patients suffer from calcium pyrophosphate dihydrate crystal depositions with occasional attacks of arthritis (pseudogout), which appears to be the result of elevated endogenous inorganic pyrophosphate (PPi) levels. These patients may also suffer articular cartilage degeneration and pyrophosphate arthropathy. Radiographs reveal pseudofractures in the lateral cortices of the proximal femora and stress fractures, and patients may experience osteopenia, chondrocalcinosis, features of pyrophosphate arthropathy, and calcific periarthritis.[19]

Odontohypophosphatasia

Odontohypophosphatasia is present when dental disease is the only clinical abnormality, and radiographic and/or histologic studies reveal no evidence of rickets or osteomalacia. Although hereditary leukocyte abnormalities and other disorders usually account for this condition, odontohypophosphatasia may explain some "early-onset periodontitis" cases.

Causes

Hypophosphatasia is associated with a molecular defect in the gene encoding tissue non-specific alkaline phosphatase (TNSALP). TNSALP is an enzyme that is tethered to the outer surface of osteoblasts and chondrocytes. TNSALP hydrolyzes several substances, including mineralization-inhibiting inorganic pyrophosphate (PPi) and pyridoxal 5’-phosphate (PLP), a major form of vitamin B. A relationship describing physiologic regulation of mineralization has been termed the Stenciling Principle of mineralization, whereby enzyme-substrate pairs imprint mineralization patterns locally into the extracellular matrix (most notably described for bone) by degrading mineralization inhibitors (e.g. TNAP/TNSALP/ALPL enzyme degrading the pyrophosphate inhibition of mineralization, and PHEX enzyme degrading the osteopontin inhibition of mineralization).[21] [22] The Stenciling Principle for mineralization is particularly relevant to the osteomalacia and odontomalacia observed in hypophosphatasia (HPP) and X-linked hypophosphatemia (XLH).[22] 6.

When TSNALP enzymatic activity is low, inorganic pyrophosphate (PPi) accumulates outside of cells in the extracellular matrix of bones and teeth, and inhibits formation of hydroxyapatite mineral, the main hardening component of bone, causing rickets in infants and children and osteomalacia (soft bones) and odontomalacia (soft teeth) in children and adults. PLP is the principal form of vitamin B6 and must be dephosphorylated by TNSALP before it can cross the cell membrane. Vitamin B6 deficiency in the brain impairs synthesis of neurotransmitters, which can cause seizures. In some cases, a build-up of calcium pyrophosphate dihydrate (CPPD) crystals in the joint can cause pseudogout.[23]

Genetics

Perinatal and infantile hypophosphatasia are inherited as autosomal recessive traits with homozygosity or compound heterozygosity for two defective TNSALP alleles. The mode of inheritance for childhood, adult, and odonto forms of hypophosphatasia can be either autosomal dominant or recessive. Autosomal transmission accounts for the fact that the disease affects males and females with equal frequency. Genetic counseling is complicated by the disease's variable inheritance pattern, and by incomplete penetration of the trait.[24]

Hypophosphatasia is a rare disease that has been reported worldwide and appears to affect individuals of all ethnicities.[5] The prevalence of severe hypophosphatasia is estimated to be 1:100,000 in a population of largely Anglo-Saxon origin. The frequency of mild hypophosphatasia is more challenging to assess because the symptoms may escape notice or be misdiagnosed. The highest incidence of hypophosphatasia has been reported in the Mennonite population in Manitoba, Canada where one in every 25 individuals are considered carriers and one in every 2,500 newborns exhibits severe disease.[25] Hypophosphatasia is considered particularly rare in people of African ancestry in the U.S.[26]

Diagnosis

Dental findings

Hypophosphatasia is often discovered because of an early loss of deciduous (baby or primary) teeth with the root intact. Researchers have recently documented a positive correlation between dental abnormalities and clinical phenotype. Poor dentition is also noted in adults.

Laboratory testing

The symptom that best characterizes hypophosphatasia is low serum activity of alkaline phosphatase enzyme (ALP). In general, lower levels of enzyme activity correlate with more severe symptoms. The decrease in ALP activity leads to an increase in pyridoxal 5’-phosphate (PLP), which is the major form of Vitamin B6, in the blood, although tissue levels of Vitamin B6 may be unremarkable[27] and correlates with disease severity.[28] Urinary inorganic pyrophosphate (PPi) levels are elevated in most hypophosphatasia patients and, although it remains only a research technique, this increase has been reported to accurately detect carriers of the disease. In addition, most patients have an increased level of urinary phosphoethanolamine (PEA) although some may not. PLP screening is preferred over PEA due to cost and sensitivity.[29]

Tests for serum tissue-non-specific ALP (sometimes referred to as TNSALP) levels are part of the standard comprehensive metabolic panel (CMP) that is used in routine exams, although bone-specific ALP testing may be indicative of disease severity.[30]

Radiography

Despite patient-to-patient variability and the diversity of radiographic findings, the X-ray is diagnostic in infantile hypophosphatasia.[31] Skeletal defects are found in nearly all patients and include hypomineralization, rachitic changes, incomplete vertebrate ossification and, occasionally, lateral bony spurs on the ulnae and fibulae.

In newborns, X-rays readily distinguish hypophosphatasia from osteogenesis imperfecta and congenital dwarfism. Some stillborn skeletons show almost no mineralization; others have marked undermineralization and severe rachitic changes. Occasionally there can be peculiar complete or partial absence of ossification in one or more vertebrae. In the skull, individual membranous bones may calcify only at their centers, making it appear that areas of the unossified calvarium have cranial sutures that are widely separated when, in fact, they are functionally closed. Small protrusions (or "tongues") of radiolucency often extend from the metaphyses into the bone shaft.

In infants, radiographic features of hypophosphatasia are striking, though generally less severe than those found in perinatal hypophosphatasia. In some newly diagnosed patients, there is an abrupt transition from relatively normal-appearing diaphyses to uncalcified metaphases, suggesting an abrupt metabolic change has occurred. Serial radiography studies can reveal the persistence of impaired skeletal mineralization (i.e. rickets), instances of sclerosis, and gradual generalized demineralization.

In adults, X-rays may reveal bilateral femoral pseudofractures in the lateral diaphysis. These pseudofractures may remain for years, but they may not heal until they break completely or the patient receives intramedullary fixation. These patients may also experience recurrent metatarsal fractures. DXA may show abnormal bone mineral density which may correlate with disease severity, although bone mineral density in HPP patients may not be systemically reduced.[32]

Genetic analysis

All clinical sub-types of hypophosphatasia have been traced to genetic mutations in the gene encoding TNSALP, which is localized on chromosome 1p36.1-34 in humans (ALPL; OMIM#171760). Approximately 388 distinct mutations have been described in the TNSALP gene.[33] Web site: The Tissue Nonspecific Alkaline Phosphatase Gene Mutations Database . 2009-08-14 . 2016-03-04 . https://web.archive.org/web/20160304002114/http://www.sesep.uvsq.fr/database_hypo/Mutation.html . dead . About 80% of the mutations are missense mutations. The number and diversity of mutations results in highly variable phenotypic expression, and there appears to be a correlation between genotype and phenotype in hypophosphatasia.[34] Mutation analysis is possible and available in 3 laboratories.[35]

Treatment

As of October 2015, asfotase alfa (Strensiq) has been approved by the FDA for the treatment of hypophosphatasia.

Some evidence exists to support the use of teriparatide in adult-HPP.[36] [37] [38] [39]

Current management consists of palliating symptoms, maintaining calcium balance and applying physical, occupational, dental and orthopedic interventions, as necessary.

History

It was discovered initially in 1936 but was fully named and documented by a Canadian pediatrician, John Campbell Rathbun (1915-1972), while examining and treating a baby boy with very low levels of alkaline phosphatase in 1948. The genetic basis of the disease was mapped out only some 40 years later. Hypophosphatasia is sometimes called Rathbun's syndrome after its principal documenter.[54] [55]

See also

Further reading

Notes and References

  1. Web site: Hypophosphatasia . Genetics Home Reference .
  2. Orimo H . Pathophysiology of hypophosphatasia and the potential role of asfotase alfa . English . Therapeutics and Clinical Risk Management . 12 . 777–786 . 2016-05-17 . 27274262 . 4876073 . 10.2147/TCRM.S87956 . free .
  3. Book: Whyte MP . Hypophosphatasia . Scriver CR, Beaudet AL, Sly WS, Valle D, Vogelstein B . The Metabolic & Molecular Bases of Inherited Disease . McGraw-Hill . New York . 2001 . 5313–29 . 978-0-07-913035-8 . 8th . 4.
  4. Web site: Hypophosphatasia. 2020-12-24. NORD (National Organization for Rare Disorders). en-US.
  5. Fraser D . Hypophosphatasia . The American Journal of Medicine . 22 . 5 . 730–746 . May 1957 . 13410963 . 10.1016/0002-9343(57)90124-9 .
  6. García-Fontana C, Villa-Suárez JM, Andújar-Vera F, González-Salvatierra S, Martínez-Navajas G, Real PJ, Gómez Vida JM, de Haro T, García-Fontana B, Muñoz-Torres M . 6 . Epidemiological, Clinical and Genetic Study of Hypophosphatasia in A Spanish Population: Identification of Two Novel Mutations in The Alpl Gene . Scientific Reports . 9 . 1 . 9569 . July 2019 . 31267001 . 6606844 . 10.1038/s41598-019-46004-2 . 2019NatSR...9.9569G .
  7. Fukushima K, Kawai-Kowase K, Yonemoto Y, Fujiwara M, Sato H, Sato M, Kubota T, Ozono K, Tamura J . 6 . Adult hypophosphatasia with compound heterozygous p.Phe327Leu missense and c.1559delT frameshift mutations in tissue-nonspecific alkaline phosphatase gene: a case report . Journal of Medical Case Reports . 13 . 1 . 101 . April 2019 . 31014398 . 6480864 . 10.1186/s13256-019-2045-4 . free .
  8. Colazo JM, Hu JR, Dahir KM, Simmons JH . Neurological symptoms in Hypophosphatasia . Osteoporosis International . 30 . 2 . 469–480 . February 2019 . 30215116 . 10.1007/s00198-018-4691-6 . 52273027 .
  9. Magdaleno AL, Singh S, Venkataraman S, Perilli GA, Lee YY . Adult-Onset Hypophosphatasia: Before and After Treatment with Asfotase ALFA . English . AACE Clinical Case Reports . 5 . 6 . e344–e348 . November 2019 . 31967067 . 6873847 . 10.4158/ACCR-2019-0143 .
  10. Web site: Hypophosphatasia May Be Misdiagnosed as Fibromyalgia: A Single Center Experience. 2021-01-05. ACR Meeting Abstracts. en-US.
  11. Jaruratanasirikul S, Chanvitan P . Hypophosphatasia: the importance of alkaline phosphatase in bone mineralization . Journal of the Medical Association of Thailand = Chotmaihet Thangphaet . 82 . 12 . 1268–1272 . December 1999 . 10659574 .
  12. Baumgartner-Sigl S, Haberlandt E, Mumm S, Scholl-Bürgi S, Sergi C, Ryan L, Ericson KL, Whyte MP, Högler W . 6 . Pyridoxine-responsive seizures as the first symptom of infantile hypophosphatasia caused by two novel missense mutations (c.677T>C, p.M226T; c.1112C>T, p.T371I) of the tissue-nonspecific alkaline phosphatase gene . Bone . 40 . 6 . 1655–1661 . June 2007 . 17395561 . 10.1016/j.bone.2007.01.020 .
  13. Millán JL, Plotkin H . Hypophosphatasia - pathophysiology and treatment . Actualizaciones en Osteologia . 8 . 3 . 164–182 . September 2012 . 25254037 . 4171060 .
  14. Villa-Suárez JM, García-Fontana C, Andújar-Vera F, González-Salvatierra S, de Haro-Muñoz T, Contreras-Bolívar V, García-Fontana B, Muñoz-Torres M . 6 . Hypophosphatasia: A Unique Disorder of Bone Mineralization . International Journal of Molecular Sciences . 22 . 9 . 4303 . April 2021 . 33919113 . 8122659 . 10.3390/ijms22094303 . free .
  15. Web site: Hypophosphatasia Signs and Symptoms. Hypophosphatasia.com. 10 September 2014. 15 October 2014. https://web.archive.org/web/20141015143435/http://www.hypophosphatasia.com/what-hypophosphatasia/signs-and-symptoms. dead.
  16. Shohat . M. . Rimoin . D. L. . Gruber . H. E. . Lachman . R. S. . Perinatal lethal hypophosphatasia; Clinical, radiologic and morphologic findings . Pediatric Radiology . Springer Science and Business Media LLC . 21 . 6 . 1991 . 0301-0449 . 10.1007/bf02026677 . 421–427. 1749675 . 1088742 .
  17. Foster BL, Nociti FH, Somerman MJ . The rachitic tooth . Endocrine Reviews . 35 . 1 . 1–34 . February 2014 . 23939820 . 3895863 . 10.1210/er.2013-1009 .
  18. Vogt M, Girschick H, Schweitzer T, Benoit C, Holl-Wieden A, Seefried L, Jakob F, Hofmann C . 6 . Pediatric hypophosphatasia: lessons learned from a retrospective single-center chart review of 50 children . Orphanet Journal of Rare Diseases . 15 . 1 . 212 . August 2020 . 32811521 . 7436954 . 10.1186/s13023-020-01500-x . free .
  19. Marini F, Brandi ML . Atypical femur fractures: a distinctive tract of adult hypophosphatasia . Clinical Cases in Mineral and Bone Metabolism . 14 . 3 . 324–328 . 2017 . 29354161 . 5762223 . 10.11138/ccmbm/2017.14.3.324 .
  20. Whyte MP . Hypophosphatasia: An overview For 2017 . Bone . 102 . 15–25 . September 2017 . 28238808 . 10.1016/j.bone.2017.02.011 . Rare Bone Diseases .
  21. Reznikov N, Hoac B, Buss DJ, Addison WN, Barros NM, McKee MD . Biological stenciling of mineralization in the skeleton: Local enzymatic removal of inhibitors in the extracellular matrix . Bone . 138 . 115447 . September 2020 . 32454257 . 10.1016/j.bone.2020.115447 . 218909350 .
  22. McKee MD, Buss DJ, Reznikov N . Mineral tessellation in bone and the stenciling principle for extracellular matrix mineralization . Journal of Structural Biology . 214 . 1 . 107823 . March 2022 . 34915130 . 10.1016/j.jsb.2021.107823 . 245187449 .
  23. Web site: T3DB: Pyrophosphate . T3DB . October 2, 2014 . October 19, 2023.
  24. Simon-Bouy B, Taillandier A, Fauvert D, Brun-Heath I, Serre JL, Armengod CG, Bialer MG, Mathieu M, Cousin J, Chitayat D, Liebelt J, Feldman B, Gérard-Blanluet M, Körtge-Jung S, King C, Laivuori H, Le Merrer M, Mehta S, Jern C, Sharif S, Prieur F, Gillessen-Kaesbach G, Zankl A, Mornet E . 6 . Hypophosphatasia: molecular testing of 19 prenatal cases and discussion about genetic counseling . Prenatal Diagnosis . 28 . 11 . 993–998 . November 2008 . 18925618 . 10.1002/pd.2088 . 33682973 . free .
  25. Greenberg CR, Taylor CL, Haworth JC, Seargeant LE, Philipps S, Triggs-Raine B, Chodirker BN . A homoallelic Gly317-->Asp mutation in ALPL causes the perinatal (lethal) form of hypophosphatasia in Canadian mennonites . Genomics . 17 . 1 . 215–217 . July 1993 . 8406453 . 10.1006/geno.1993.1305 .
  26. Whyte MP, Essmyer K, Geimer M, Mumm S . Homozygosity for TNSALP mutation 1348c>T (Arg433Cys) causes infantile hypophosphatasia manifesting transient disease correction and variably lethal outcome in a kindred of black ancestry . The Journal of Pediatrics . 148 . 6 . 753–758 . June 2006 . 16769381 . 10.1016/j.jpeds.2006.01.031 .
  27. Whyte MP, Mahuren JD, Fedde KN, Cole FS, McCabe ER, Coburn SP . Perinatal hypophosphatasia: tissue levels of vitamin B6 are unremarkable despite markedly increased circulating concentrations of pyridoxal-5'-phosphate. Evidence for an ectoenzyme role for tissue-nonspecific alkaline phosphatase . The Journal of Clinical Investigation . 81 . 4 . 1234–1239 . April 1988 . 3350970 . 329654 . 10.1172/JCI113440 . free .
  28. Schmidt T, Mussawy H, Rolvien T, Hawellek T, Hubert J, Rüther W, Amling M, Barvencik F . 6 . Clinical, radiographic and biochemical characteristics of adult hypophosphatasia . Osteoporosis International . 28 . 9 . 2653–2662 . September 2017 . 28547134 . 10.1007/s00198-017-4087-z . 25864719 .
  29. Web site: Hypophosphatasia. 2021-09-28. NORD (National Organization for Rare Disorders). en-US.
  30. Whyte MP, Walkenhorst DA, Fedde KN, Henthorn PS, Hill CS . Hypophosphatasia: levels of bone alkaline phosphatase immunoreactivity in serum reflect disease severity . The Journal of Clinical Endocrinology and Metabolism . 81 . 6 . 2142–2148 . June 1996 . 8964842 . 10.1210/jcem.81.6.8964842 . free .
  31. Shohat M, Rimoin DL, Gruber HE, Lachman RS . Perinatal lethal hypophosphatasia; clinical, radiologic and morphologic findings . Pediatric Radiology . 21 . 6 . 421–427 . 1991 . 1749675 . 10.1007/BF02026677 . 1088742 .
  32. Genest F, Claußen L, Rak D, Seefried L . Bone mineral density and fracture risk in adult patients with hypophosphatasia . Osteoporosis International . 32 . 2 . 377–385 . February 2021 . 32879991 . 7838076 . 10.1007/s00198-020-05612-9 . free .
  33. Choida V, Bubbear JS . Update on the management of hypophosphatasia . Therapeutic Advances in Musculoskeletal Disease . 11 . 1759720X19863997 . 2019-01-01 . 31413732 . 6676257 . 10.1177/1759720X19863997 .
  34. Zurutuza L, Muller F, Gibrat JF, Taillandier A, Simon-Bouy B, Serre JL, Mornet E . Correlations of genotype and phenotype in hypophosphatasia . Human Molecular Genetics . 8 . 6 . 1039–1046 . June 1999 . 10332035 . 10.1093/hmg/8.6.1039 . free .
  35. Web site: geneteset.org homepage .
  36. Lawrence JE, Saeed D, Bartlett J, Carrothers AD . Adult-onset hypophosphatasia diagnosed following bilateral atypical femoral fractures in a 55-year-old woman . Clinical Cases in Mineral and Bone Metabolism . 14 . 3 . 347–353 . 2017 . 29354166 . 5762228 . 10.11138/ccmbm/2017.14.3.347 .
  37. Whyte MP . Hypophosphatasia - aetiology, nosology, pathogenesis, diagnosis and treatment . Nature Reviews. Endocrinology . 12 . 4 . 233–246 . April 2016 . 26893260 . 10.1038/nrendo.2016.14 . 20805434 .
  38. Camacho PM, Mazhari AM, Wilczynski C, Kadanoff R, Mumm S, Whyte MP . Adult Hypophosphatasia Treated with Teriparatide: Report of 2 Patients and Review of the Literature . Endocrine Practice . 22 . 8 . 941–950 . August 2016 . 27042741 . 10.4158/EP15890.OR .
  39. Whyte MP, Mumm S, Deal C . Adult hypophosphatasia treated with teriparatide . The Journal of Clinical Endocrinology and Metabolism . 92 . 4 . 1203–1208 . April 2007 . 17213282 . 10.1210/jc.2006-1902 . free .
  40. Barcia JP, Strife CF, Langman CB . Infantile hypophosphatasia: treatment options to control hypercalcemia, hypercalciuria, and chronic bone demineralization . The Journal of Pediatrics . 130 . 5 . 825–828 . May 1997 . 9152296 . 10.1016/S0022-3476(97)80029-7 .
  41. Opshaug O, Maurseth K, Howlid H, Aksnes L, Aarskog D . Vitamin D metabolism in hypophosphatasia . Acta Paediatrica Scandinavica . 71 . 3 . 517–521 . May 1982 . 6291316 . 10.1111/j.1651-2227.1982.tb09466.x . 25957674 .
  42. Collmann H, Mornet E, Gattenlöhner S, Beck C, Girschick H . Neurosurgical aspects of childhood hypophosphatasia . Child's Nervous System . 25 . 2 . 217–223 . February 2009 . 18769927 . 10.1007/s00381-008-0708-3 . 9470770 .
  43. Coe JD, Murphy WA, Whyte MP . Management of femoral fractures and pseudofractures in adult hypophosphatasia . The Journal of Bone and Joint Surgery. American Volume . 68 . 7 . 981–990 . September 1986 . 3745261 . 10.2106/00004623-198668070-00004 .
  44. Reibel A, Manière MC, Clauss F, Droz D, Alembik Y, Mornet E, Bloch-Zupan A . Orodental phenotype and genotype findings in all subtypes of hypophosphatasia . Orphanet Journal of Rare Diseases . 4 . 6 . February 2009 . 19232125 . 2654544 . 10.1186/1750-1172-4-6 . free .
  45. Girschick HJ, Seyberth HW, Huppertz HI . Treatment of childhood hypophosphatasia with nonsteroidal antiinflammatory drugs . Bone . 25 . 5 . 603–607 . November 1999 . 10574582 . 10.1016/S8756-3282(99)00203-3 .
  46. Deeb AA, Bruce SN, Morris AA, Cheetham TD . Infantile hypophosphatasia: disappointing results of treatment . Acta Paediatrica . 89 . 6 . 730–733 . June 2000 . 10914973 . 10.1080/080352500750044106 .
  47. Whyte MP, Kurtzberg J, McAlister WH, Mumm S, Podgornik MN, Coburn SP, Ryan LM, Miller CR, Gottesman GS, Smith AK, Douville J, Waters-Pick B, Armstrong RD, Martin PL . 6 . Marrow cell transplantation for infantile hypophosphatasia . Journal of Bone and Mineral Research . 18 . 4 . 624–636 . April 2003 . 12674323 . 10.1359/jbmr.2003.18.4.624 . free .
  48. Cahill RA, Wenkert D, Perlman SA, Steele A, Coburn SP, McAlister WH, Mumm S, Whyte MP . 6 . Infantile hypophosphatasia: transplantation therapy trial using bone fragments and cultured osteoblasts . The Journal of Clinical Endocrinology and Metabolism . 92 . 8 . 2923–2930 . August 2007 . 17519318 . 10.1210/jc.2006-2131 . free .
  49. Whyte MP, Valdes R, Ryan LM, McAlister WH . Infantile hypophosphatasia: enzyme replacement therapy by intravenous infusion of alkaline phosphatase-rich plasma from patients with Paget bone disease . The Journal of Pediatrics . 101 . 3 . 379–386 . September 1982 . 7108657 . 10.1016/S0022-3476(82)80061-9 .
  50. Whyte MP, McAlister WH, Patton LS, Magill HL, Fallon MD, Lorentz WB, Herrod HG . Enzyme replacement therapy for infantile hypophosphatasia attempted by intravenous infusions of alkaline phosphatase-rich Paget plasma: results in three additional patients . The Journal of Pediatrics . 105 . 6 . 926–933 . December 1984 . 6502342 . 10.1016/S0022-3476(84)80079-7 .
  51. Web site: Clinical Trials website. U.S. National Institutes of Health.
  52. Web site: enobia.com. www.enobia.com.
  53. Güzel Nur B, Çelmeli G, Manguoğlu E, Soyucen E, Bircan İ, Mıhçı E . Pyridoxine-Responsive Seizures in Infantile Hypophosphatasia and a Novel Homozygous Mutation in ALPL Gene . Journal of Clinical Research in Pediatric Endocrinology . 8 . 3 . 360–364 . September 2016 . 27086862 . 5096504 . 10.4274/jcrpe.2798 .
  54. Web site: Our Mission. Soft Bones Canada Inc.. Taillefer D .
  55. Web site: Rogers K, Chauhan Y . Hypophosphatasia . Encyclopedia Britannica . 2013-09-30. 2021-08-23 .